Method of manufacturing rotary driving device and the same device

Abstract

A method of manufacturing a rotary driving device is disclosed. The method includes the steps of mounting a turntable, which is equipped with an anti-slipping section on a disc-placeable surface, to a rotary shaft; rotating the turntable; and shaving off a disc-contact surface, with which a disc contacts when the disc is placed, of the anti-slipping section with a cutting tool through a cutting off machining method from outside of the disc-placeable surface toward the rotary shaft. A cutting edge of the cutting tool is placed widthwise in parallel with an end face of the anti-slipping section and thickness-wise along an axial direction of the rotary shaft. The cutting edge is set such that the sections of the tool other than the cutting edge do not touch the anti-slipping section.

Description

FIELD OF THE INVENTION [0001] The present invention relates to manufacturing methods of driving devices, such as a spindle motor, for driving rotary units such as recording discs in the optical media field, e.g. CD-ROM(R), DVD-ROM(R) and DVD-RAM, and it also relates to the same driving devices. BACKGROUND OF THE INVENTION [0002] A spindle motor, one of the examples of driving devices, is used for driving disc-shaped recording media such as CD-ROM(R) disc, DVD-ROM(R) disc and DVD-RAM disc. The spindle motor often employs a brush-less DC motor, and is equipped with a turntable, on which a recording medium (an example of rotary units) is mounted, and a driving section for driving the turntable. [0003] The driving section comprises the following elements: [0004] a motor frame; [0005] a rotor supported rotatably by the motor frame; and [0006] a stator placed in the motor frame such that it surrounds and confronts the rotor. The turntable and the rotor need to synchronize their rotations...

AI Technical Summary

Benefits of technology

[0032] This method allows achieving not only a high accuracy of surface wobble, i.e. vertical deviation, of the anti-slipping section on the disc-placeable surface of the turntable, but also a high accuracy of a surface roughness and flatness of the disc-placeable surface.

[0042] The foregoing structure allows providing a rotary driving device of which disc-placeable surface of the turntable having an anti-slipping section that is finished with not only a high accuracy of the vertical deviation, but also a high accuracy of a surface roughness and flatness.

Problems solved by technology

When the spindle motor wobbles during its operation, the recording medium mounted to the motor also wobbles, then a distance between the medium and the head placed closely to the medium changes, so that information cannot be sometimes read or written correctly from or to the medium.

As a result, the vertical deviation due to motor rotation differs in respective spindle motors, and uniform vertical deviations cannot be expected.

CD-ROM disc driving devices and DVD-ROM disc dividing devices, among others, frequently repeat acceleration to a higher rpm and deceleration to a lower rpm, so that abrupt change of torque works, which tends to produce slips between the turntable and the disc.

However, this conventional turntable has encountered the following problems: difficulty of manufacturing the anti-slipping member at a uniform thickness, and difficulty of applying the adhesive at a uniform thickness.

Those problems cause the vertical deviation of the turntable.

However, the foregoing turntable, of which disc-placeable surface is coated with one of a variety of anti-slipping films, has a limit to keep down the dispersion in accuracy of mounting the turntable to the rotary shaft.

It is thus difficult to achieve the more strict accuracy of vertical deviation.

As a memory capacity and a reading speed of optical-medium increase, inner disturbing vibrations generated by motor rotations and outer disturbing vibrations, such as vibrations or impacts applied from the outside to the driving devices, have drawn attention as another problem.

As a result, an optical pickup cannot read or write signals from / to the disc, so that the device cannot work properly.

However, it is difficult to finish any one of the members previously discussed with a high accuracy by the shaving described in patent document 2 or the polishing described in patent document 3.

The members have problems in the processing (machining or polishing), and a hardness of the anti-slipping members cannot be further increased because of maintaining the anti-slipping property.

This is another factor to make the processing more difficult.

Although the foregoing conventional processing method of the anti-slipping section of the disc-placeable surface is indeed good enough for achieving a higher accuracy of vertical deviation, the conventional method encounters difficulty of finishing the anti-slipping face with a high accuracy both in a surface roughness and flatness.

Since the anti-slipping member is made of rubber or resin, an edge of the cutting tool tends to gather cut-chips thereon during the shaving, so that a temperature at the edge rapidly rises, thereby shortening the life of the cutting tool.

It is thus difficult to satisfy both of the requirements (i.e. long life of the tool and avoidance of cut-chips).

It is also very difficult to polish soft material such as rubber or resin with a whetstone, because the surface subjected to polishing tends to be rough and produce much abrasive powder.

A smaller roughness cannot be expected, and the abrasive powder easily attach to the surface, so that the flatness tends to lower.

In the case of the multi-layer structure including the damping vibration elastic layer which damps vibrations generated on discs, since plural materials are layered, it is more difficult to achieve a higher accuracy with the foregoing shaving or polishing.

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